A gas turbine engine is a rotating device that uses the action of a fluid to produce work. In a gas turbine engine, a pressurized, high temperature gas is the driving force. One of the reasons that gas turbine engines are widely used to power aircraft is they are light and compact and have a high power-to-weight ratio.
Gas turbine engines typically include several stages including a fan, a compressor, a combustor, and a turbine. Some of these stages utilize rotating airfoils with shaped blades arranged in series. The blades convert energy from combustion gases produced by the combustor into mechanical work used to turn a rotor. The blades positioned forward of the combustor are turned by the rotor to compress air entering the combustor.
Blades usually have a clearance gap between the blade tip and the stationary casing or the shroud surface adjacent the blade tip. This clearance gap is typically called a tip gap. This clearance gap is necessary to allow for rotation of the blade and to allow for mechanical and thermal growth of the blade. Due to the pressure difference between the pressure side and the suction side of the blade, hot gas leaks across this gap from the pressure side to the suction side. This phenomenon is known as tip leakage flow.
The tip leakage flow results in a reduction in the blade force, (e.g., the work done) and therefore, the overall efficiency of the gas turbine engine. In fact, the losses that are attributed to leakage flow can be very substantial. Leakage flow also increases the thermal loading on the blade tip, leading to high local temperatures adjacent the tip, and thus, is considered one of the primary sources of blade failure. Typically, leakage flow is reduced by using a recessed or squealer tip blade or by modifying the blade tip to incorporate film cooling.
Blades, including turbine blades in particular, can utilize a pocket recess which comprises a recess cavity that extends radially through the length of the blade. The pocket recess creates an opening at the tip of the blade. The pocket recess is used for efficiency purposes to reduce the weight of the blade and to reduce blade creep. However, due to excessive blade tip leakage, the efficiency of the pocket recess is limited.
An airfoil includes, a blade having a leading edge, a trailing edge, a pressure side, a suction side, a tip, and a scoop. The scoop extends along the tip of the blade. The scoop comprises a difference in a radial height of the blade from a pressure side to a suction side of the blade. The radial height of the blade at the pressure side is less than the radial height of the blade at the suction side.
In another aspect, a blade includes an outer radial surface disposed along a suction side of a tip of the blade, an inner radial surface disposed along a pressure side of the tip of the blade, and a pocket recess. The inner radial surface has a different radial height than the outer radial surface. The pocket recess is open at the tip of the blade and is disposed between the inner radial surface and the outer radial surface.
Airfoil 8A is of conventional design and includes a blade 10A extending generally radially outward from a platform section (not numbered) and a root section (not numbered) to blade tip 12A. When installed, blade tip 12A is disposed adjacent gas turbine engine stator case (not shown). Pocket recess 14A extends into blade 10A at blade tip 12A. In the embodiment shown in
Blade 10A extends from leading edge 18A along concave pressure surface 22A and along convex suction surface 24A to trailing edge 20A. For reference purposes, camber line 16A extends along blade tip 12A from leading edge 18A to trailing edge 20A. Pocket recess 14A is separated from exterior of blade 10A and pressure surface 22A by first wall 32A. Similarly, pocket recess 14A is separated from exterior of blade 10A and suction surface 24A by second wall 34A. Because pocket recess 14A is symmetric with respect to camber line 16A, first wall 32A has substantially a same thickness as second wall 34A along a corresponding extent of pocket recess 14A.
Scoop 26A extends along blade tip 12A from leading edge 18A to trailing edge 20A. Thus, in the embodiment shown both outer radial surface 28A and inner radial surface 30A of blade tip 12A extend from leading edge 18A to trailing edge 20A. Scoop 26A comprises a cutout along a pressure side of blade 10A. Thus, scoop 26A forms step feature that extends along blade tip 12A. In the embodiment shown, the step or change in radial height H in blade 10A between outer radial surface 28A and inner radial surface 30A is generally aligned on camber line 16A. Outer radial surface 28A extends along a suction side of blade tip 12A and inner radial surface 30A extends along a pressure side of blade tip 12A.
Because the construction and operation of gas turbine engines is known in the art, gas turbine engine will not be discussed in great detail. While blade 10A is shown as a separate component removable from a rotor (not shown) in other embodiments airfoil can be integrated with the rotor. Although described with reference to a turbine airfoil, in other embodiments blade can be utilized in the compressor or other stage of the gas turbine engine.
Consider an incompressible inviscid turbine tip clearance flow field; the flow through the tip gap is obtained from Bernoulli equation is as shown in Equation 1:
Where Pp=Pressure side pressure, Ps=Suction side pressure, ρ=. Gas density, and WL=Leakage flow.
As shown in
As previously discussed, creation of counter rotating vortex V at blade tip 12A leads to a reduction in blade tip leakage TL, which results in improved gas turbine engine efficiency and fuel savings. Operating temperatures within the turbine engine can be increased as a result of decreased temperature localization, which results in reduced emissions. Additionally, reduced blade tip leakage TL results in extended hot section durability due to a reduction in the thermal loading on the blade tip 12A. In instances of disc-blade coupling mistuning, a turbine wheel with tip modification as described would result in tuning out the interfered frequency and also aids in maintaining a balanced rotor.
Scoop 26A comprises a curved step between outer radial surface 28A and inner radial surface 30A and extends the entire length of blade tip 12A from leading edge 18A to trailing edge 20A. Radial height H between outer radial surface 28A and inner radial surface 30A will vary from embodiment to embodiment. In one embodiment, the radial height H is greater than or equal to the tip clearance (the distance between the stator casing and the outermost radial extent of blade tip 12A) and is less than or equal to about 15% of the blade span. Radius R is greater than or equal to height H. Aft length L1 and a forward length L2 along step feature between outer radial surface 28A and inner radial surface 30A will vary from embodiment to embodiment and vary as a function of pocket axial length, pocket configuration, and step lateral thickness (expressed in term of T1 and T2).
Pocket recess 14B extends into blade 10B from blade tip 12B. In the embodiment shown in
For reference purposes, camber line 16B extends along blade tip 12B from leading edge 18B to trailing edge 20B. Blade 10B extends from leading edge 18B along concave pressure surface 22B and along convex suction surface 24B to trailing edge 20B. Scoop 26B is biased away from camber line 16B toward pressure side. Scoop 26B extends along blade tip 12B from leading edge 18B and trailing edge 20B. Thus, in the embodiment shown inner radial surface 30B and outer radial surface 28B of blade tip 12B extend from leading edge 18B to trailing edge 20B. Scoop 26A comprises a cutout or step feature that extends along blade tip 12B.
Due to the changes in the configuration of scoop 26B and pocket recess 14B compared to the embodiments of
Pocket recess 14C extends into blade 10C from blade tip 12C. In the embodiment shown in
Blade 10C extends from leading edge 18C along concave pressure surface 22C and along convex suction surface 24C to trailing edge 20C. For reference purposes, camber line 16C extends along blade tip 12C from leading edge 18C to trailing edge 20C. Step between outer radial surface 28C and inner radial surface 30C runs along and straddles camber line 16C. Scoop 26C is of a reduced size and is offset from camber line 16C. Thus, scoop 26C is asymmetric with respect to camber line 16C. Therefore, outer radial surface 28C has a lateral thickness T1 along camber line 16C that differs from a corresponding lateral thickness T2 of inner radial surface 30C (T1<T2) and scoop 26C extends from leading edge 18C to trailing edge 20C. Due to the changes in position of pocket cavity 14C compared to the embodiments of
Pocket recess 14D extends into blade 10D from blade tip 12D. In the embodiment shown in
Scoop 26D is disposed asymmetrically with respect to camber line 16D such that step feature does not straddle or follow camber line 16D. Rather, outer radial surface 28D has a thickness T1 along camber line 16D that differs from a corresponding thickness T2 of inner radial surface 30D. During aft length L1 of scoop 26D outer radial surface 28D thickness T1 is less than corresponding thickness T2 of inner radial surface 30D. During forward length L2 of scoop 26D, outer radial surface 28D thickness T1 is greater than corresponding thickness T2 of inner radial surface 30D.
An asymmetric pocket cavity such as pocket cavities 14B, 14C, and 14D alters the mass/stiffness of the blade 10B, 10C, and 10D, thereby shifting or tuning away the natural frequency of the pocket cavity and blade from the frequency of acoustic pressure oscillation or the frequency of the aero-excitation source.
More particularly, blade can be tuned at blade anti-nodes as further discussed in United States Patent Application Publications 2010/0278632A and 2010/0278633A, which are incorporated herein by reference. Tuning is performed by modifying the stiffness/mass (i.e. wall thickness) at one or more blade anti-nodes. Increasing the mass at the blade anti-node decreases natural frequency, and decreasing mass at blade anti-node increases natural frequency. Wall thickness as a result of pocket recess geometry can be modified until the natural frequency of the blade resonant mode shapes that have interferences are moved out of the expected acoustic pressure oscillation frequency or out of the aero-excitation source frequency. Wall thickness as a result of the pocket recess geometry can be further modified to further increase a substantially resonance-free running range. If further tuning is desired, the pocket recess geometry can be modified on one or more additional blade anti-nodes until the blade has no natural frequencies that excite at the expected acoustic pressure oscillation frequency or aero-excitation frequency. The natural frequency of the blade resonant mode shapes can be modeled using a finite element method.
While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.